DOCSLIB.ORG

Tools of Astronomy Notes Light Is a Form of Electromagnetic Radiation

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Tools of Astronomy Notes Light Is a Form of Electromagnetic Radiation Name_________________________________________Date____________________Period__ Tools of Astronomy Notes Light is a form of electromagnetic radiation. Scientists call the light you can see visible light. If you shine white light through a prism, the light spreads out to make a range of different colors with different wavelengths, called a spectrum. The electromagnetic spectrum includes the entire range of radio waves, microwaves infrared, visible light, ultraviolet radiation, X-rays, and gamma rays. Telescopes are instruments that collect and focus light and other forms of electromagnetic radiation. A telescope that uses lenses or mirrors to collect and focus visible light is called an optical telescope. The two major types of optical telescopes are refracting telescopes and reflecting telescopes. Telescopes used to detect radio waves from objects in space are called radio telescopes. Most radio telescopes have curved, reflecting surfaces. As with optical telescopes, the larger a radio telescope is, the more radio waves it can collect. Radio telescopes can be used day or night. They can also be used during cloudy weather because radio waves can pass through clouds. Most ultraviolet radiation, X-rays, and gamma rays are blocked by Earth’s atmosphere. To detect these wavelengths, astronomers have placed the Hubble space telescope in space. Some space telescopes also detect visible light or infrared radiation. The Earth’s atmosphere interferes with of these forms of radiation. By placing a telescope in space astronomers get a clearer picture of the universe. Spectroscopes are another useful tool for astronomers. A spectroscope breaks the light from a star into a spectrum. Each element has a unique spectrum. This allows astronomers to compare the spectrum of a star to known elements. Using this technique, called spectral analysis, astronomers can determine what a star made of is without going there. Name_________________________________________Date____________________Period__ Understanding Telescopes Background Most of the universe is invisible to us because we only see the visible light portion of the electromagnetic spectrum. In other words, when you look at a planet, let’s say Mars, through most telescopes you are only seeing the portion of the spectrum that can be made visible by special cells in the human eye. We call these types of telescopes optical telescopes since they only collect visible energy. However; there are other ways to “see” the universe. There are two basic types of optical telescopes, refractors and reflectors Refracting telescopes (lenses) use lenses to gather and bend light making things seem larger. The lenses used in refracting telescopes are called concave and convex. Convex lenses make light bend inward. Concave lenses bend light outward. The combination of these two lenses makes things seem bigger and clearer. Reflecting telescopes (mirrors) use mirrors and lenses to collect and magnify light. With a reflecting telescope, light is collected by a big concave mirror. Concave mirrors focus light inward. The mirror reflects light to a smaller flat mirror. This secondary mirror directs the light through the eyepiece lens at the side of the telescope. The eyepiece magnifies the image and directs it to your eye. We have seen how visible light is used in optical telescopes. Visible light, however, is only a small part of the electromagnetic spectrum. In recent years the remainder of the electromagnetic spectrum has revealed extensive information about our Universe. One non-visual light wave used extensively for astronomical observations is the radio frequency band. Telescopes observing at these wavelengths are commonly called radio telescopes. Although they do not look like optical telescopes, radio telescopes are built to accomplish the same gathering and focusing tasks that optical telescopes perform on visible light. Name_________________________________________Date____________________Period__ A radio telescope typically consists of a parabolic (bowl- shaped) antenna similar to a modern satellite dish. This dish collects incoming radio or microwave radiation and focuses it onto a sensitive receiver located behind or below the antenna. Inside the receiver, the incoming waves are converted into electrical signals. Computers then process those signals to form images of the sky as it would look if our eyes were able to see at radio or microwave frequencies Radio telescopes have some clear advantages over optical telescopes. Radio telescopes can be used both day and night. They can also be used on cloudy days, because radio waves can pass through clouds. Over the last half-century, radio astronomers have used radio telescopes to make important discoveries. By studying the sky with both radio and optical telescopes, astronomers gain a much more complete understanding of the universe. The Hubble Space Telescope (HST) is a NASA telescope which was launched in 1990 into a low-Earth orbit 600 km above the ground. During its lifetime Hubble has become one of the most important science projects ever. Hubble's orbit above the Earth's atmosphere allows astronomers to see very clear images of space. The advantage of using a telescope in space is that you don't have to look through the Earth's atmosphere. It is a real advantage to get above the atmosphere. Hubble Space Telescope pictures are much more detailed than you can get from the ground. Hubble can also access the ultraviolet and infrared parts of the spectrum not visible from the ground. **The diagrams below show how light is bent by lenses and mirrors. This information will be used in part two of the answer sheet. Name_________________________________________Date____________________Period__ Understanding Telescopes Answer Sheet Part One Questions: 1. What are the two main types of optical telescopes? a. __________________________ b. __________________________ 2. Which type of telescope only uses lenses to focus the light? __________________________________ 3. Which type of telescope uses both lenses and mirrors to focus the light? __________________________________ 4. What type of light does a radio telescope use to study the universe? __________________________________ 5. What are the advantages that a radio telescope has over optical telescopes? ______________________________________________________________________________ ______________________________________________________________________________ ______________________________________________________________________________ ______________________________________________________________________________ 6. What is the Hubble Space Telescope (HST)? ______________________________________________________________________________ ______________________________________________________________________________ 7. What are the advantages that the HST has over Earth based telescopes? ______________________________________________________________________________ ______________________________________________________________________________ ______________________________________________________________________________ ______________________________________________________________________________ Name_________________________________________Date____________________Period__ Part Two Questions: The diagrams below show a variety of reflecting and refracting telescope designs. Refer to the diagrams of how mirrors and lenses bend light to determine how light travels through each telescope. Follow the light from where it enters the telescope to the eyepiece. Use a ruler to draw straight lines. 8. 9. 10. 11. .
Load more

Recommended publications
  • Galileo and the Telescope
    Galileo and the Telescope A Discussion of Galileo Galilei and the Beginning of Modern Observational Astronomy ___________________________ Billy Teets, Ph.D. Acting Director and Outreach Astronomer, Vanderbilt University Dyer Observatory Tuesday, October 20, 2020 Image Credit: Giuseppe Bertini General Outline • Telescopes/Galileo’s Telescopes • Observations of the Moon • Observations of Jupiter • Observations of Other Planets • The Milky Way • Sunspots Brief History of the Telescope – Hans Lippershey • Dutch Spectacle Maker • Invention credited to Hans Lippershey (c. 1608 - refracting telescope) • Late 1608 – Dutch gov’t: “ a device by means of which all things at a very great distance can be seen as if they were nearby” • Is said he observed two children playing with lenses • Patent not awarded Image Source: Wikipedia Galileo and the Telescope • Created his own – 3x magnification. • Similar to what was peddled in Europe. • Learned magnification depended on the ratio of lens focal lengths. • Had to learn to grind his own lenses. Image Source: Britannica.com Image Source: Wikipedia Refracting Telescopes Bend Light Refracting Telescopes Chromatic Aberration Chromatic aberration limits ability to distinguish details Dealing with Chromatic Aberration - Stop Down Aperture Galileo used cardboard rings to limit aperture – Results were dimmer views but less chromatic aberration Galileo and the Telescope • Created his own (3x, 8-9x, 20x, etc.) • Noted by many for its military advantages August 1609 Galileo and the Telescope • First observed the
    [Show full text]
  • The Telescope Lenses, Which Turned the Image Upside Down but Improved the Clarity Dramatically
    The image produced by the first refracting telescope was Name right side up. However, the clarity of the image was less than ideal. Johannes Kepler worked to improve the image produced by the refracting telescope. He used two convex The Telescope lenses, which turned the image upside down but improved the clarity dramatically. His design soon became popular By Phyllis Naegeli and remains in use today. Do you like to lie on your back and gaze One problem associated with the refracting telescope was at the stars? What constellations can you the rainbow halo it produced around the object in view. Sir name? Have you ever used a telescope to Isaac Newton did not care for the halo produced by the get a closer look at the universe? Do you refracting telescope. He set out to improve the design, know how a telescope works? which led him to work on the reflecting telescope. The design used a curved mirror to collect light from an object. A telescope is used to see distant objects A secondary flat mirror reflected the image to the side of up close. There are two basic types of the tube where it is viewed through an eyepiece. Newton telescopes - the refracting telescope and also used a shorter, fatter tube allowing magnification to be the reflecting telescope. Each will help increased by using larger mirrors. Newton's design you to see the planets, moon, or stars. Both eliminated the rainbow halo produced by the convex lenses use a tube and have an eyepiece to focus the image for you of the refracting telescope.
    [Show full text]
  • Solar System Solar System
    Delta Science Reader SolarSolar SystemSystem Delta Science Readers are nonfiction student books that provide science background and support the experiences of hands-on activities. Every Delta Science Reader has three main sections: Think About . , People in Science, and Did You Know? Be sure to preview the reader Overview Chart on page 4, the reader itself, and the teaching suggestions on the following pages. This information will help you determine how to plan your schedule for reader selections and activity sessions. Reading for information is a key literacy skill. Use the following ideas as appropriate for your teaching style and the needs of your students. The After Reading section includes an assessment and writing links. OVERVIEW Students will: discover facts about the Solar System In the Delta Science Reader Solar System, students take a tour of the Sun and the explore the planets and other objects in the planets. Other space objects such as dwarf Solar System planets, comets, asteroids, and meteoroids discuss the function of a table of contents, are explored. Students read about the headings, and a glossary rotation and revolution of the planets and interpret photographs and graphics to the causes of night and day, seasonal answer questions changes, and the phases of the Moon. The book describes the work of a planetary complete a KWL chart geologist. In addition, students discover organize information in a variety of ways how telescopes work. delta science modules Solar System 119 © Delta Education LLC. All rights reserved.
    [Show full text]
  • The History of Optical Astronomy, by Caroline Herschel and Lyman Spitzer
    Online Modules from The University of Chicago Multiwavelength Astronomy: The History of Optical Astronomy, by Caroline Herschel and Lyman Spitzer http://ecuip.lib.uchicago.edu/multiwavelength-astronomy/optical/history/index.html Subject(s): Astronomy/Space Science Grade(s) Level: 9-12 Duration: One Class Period Objectives: As a result of reading The History of Optical Astronomy, students will be able to • Discriminate between reflecting and refracting telescope designs and describe the differences between them; • Explain how a telescope focuses light; • Articulate the limitations of ground-based telescopes and propose solutions to these limitations; • Identify important astronomical discoveries made and personages working in the optical regime; • Discuss examples of problem-solving and creativity in astronomy. Materials: Internet connection and browser for displaying the lesson. Pre-requisites: Students should be familiar with the Electromagnetic Spectrum. Before using the lesson, students should familiarize themselves with all vocabulary terms. Procedures: Students will read the lesson and answer assessment questions (listed under evaluation). Introduction: In reading this lesson, you will meet important individuals in the History of Optical Astronomy. They are: Caroline Lucretia Herschel was a German-born British astronomer and the sister of astronomer Sir William Herschel. She is the discoverer of several comets, in particular, the periodic comet 35P/Herschel-Rigollet, which bears her name. Lyman Strong Spitzer, Jr. was an American theoretical physicist, astronomer and mountaineer. He carried out research into star formation, plasma physics, and in 1946, conceived the idea of telescopes operating in outer space. Spitzer is the namesake of NASA's Spitzer Space Telescope. 1 Online Modules from The University of Chicago William Herschel was an astronomer and composer.
    [Show full text]
  • Infinity 60AZ and 70AZ Manual (Size: 2.3
    www.meade.com MEADE INSTRUCTION MANUAL 60mm | 2.4” Alt-azimuth Refracting Telescope 70mm | 2.8” Alt-azimuth Refracting Telescope INFINITY SERIES 60 & 70mm Telescopes WARNING! Never use a Meade® telescope to look at the Sun! Looking at or near the Sun will cause instant and irreversible damage to your eye. Eye damage is often painless, so there is no warning to the observer that damage has occurred until it is too late. Do not point the telescope at or near the Sun. Do not look through the telescope or viewfinder as it is moving. Children should always have adult supervision while observing. INTRODUCTION determines how much detail you will be Your telescope is an excellent beginner’s able to see in your telescope. The focal instrument, and is designed to observe length information will help later on to 1 objects in the sky and also on land. It can calculate magnification. be your personal window on the universe or allows you to intimately study the behavior of Setting up your telescope involves these nesting birds on a distant hillside. simple steps: • Setting up your tripod The telescope is shipped with the following • Attach the accessory tray parts: • Attach the optical tube to the mount • Optical tube • Attach the viewfinder • Aluminum tripod with accessory tray • Attach the diagonal mirror and eye- • Two 1.25” eyepieces: MA25mm, MA9mm piece • 90 degree erect image diagonal mirror • Align the viewfinder • 2X Barlow • Red-dot viewfinder with bracket Study the picture on the next page and • Yoke-style mount become acquainted with the parts of your telescope.
    [Show full text]
  • The UTB/TSC Physics and Astronomy Department, the Center for Gravitational Wave Astronomy, and the Brownsville Alliance for Science Education Host Mars Viewing
    The UTB/TSC Physics and Astronomy Department, the Center for Gravitational Wave Astronomy, and the Brownsville Alliance for Science Education Host Mars Viewing Quick Guide to the Mars Opposition of August 2003 What is Mars? Mars is the fourth planet from the Sun, or the next planet out from the Earth. Often visible with the unaided eye, it has long been a source of fascination. Mars is about half the size of the Earth (in diameter). Its atmosphere is much thinner than the Earth's, and is mostly carbon dioxide. The average temperature on Mars is -45° C (-50° F), although it can range from -100° to 0° C (-150° to 30° F). Liquid water cannot exist on Mars on the surface. The time for Mars to complete one orbit around the Sun, the Martian year, is 687 days or 1.88 of our years. But Mars rotates on its axis once every 24 hours and 37 minutes, very similar to our day. The surface of Mars is rock and dust. There are many craters from the impacts of comets and asteroids, but there are also vast plains with extinct volcanoes larger than any on Earth, a rift Mars as seen by the Viking 1 valley the length of the United States, and channels apparently cut by running water sometime orbiter. Valles Marineris in the past. Mars appears orange with dark brown regions of wind-blown dust. There are also (Mariner Valley) cuts across the white polar caps of ice and dry ice (frozen water and frozen carbon dioxide) which expand center from left to right.
    [Show full text]
  • Instruction Manual Starnavigator NG Series Telescopes with Audiostar®
    Instruction Manual StarNavigator NG Series Telescopes with AudioStar® MEADE.COM WARNING! ® Never use a Meade StarNavigator NG™ Telescope to look at the Sun! Looking at or near the Sun will cause instant and irreversible damage to your eye. Eye damage is often painless, so there is no warning to the observer that damage has occurred until it is too late. Do not point the telescope at or near the Sun. Do not look through the telescope or viewfinder as it is moving. Children should always have adult supervision while observing. Refracting Telescopes use a large objective lens as their primary light-collecting element. Meade refractors, in all models and apertures, include achromatic (2-element) objective lenses in order to reduce or virtually eliminate the false color (chromatic aberration) that results in the telescopic image when light passes through a lens. Reflecting Telescopes use a concave primary mirror to collect light and form an image. In the Newtonian type of reflector, light is reflected by a small, flat secondary mirror to the side of the main tube for observation of the image. Eyepiece F 2-Element Refracting Telescope Objective Lens In the refracting telescope, light is collected by a 2-element objective lens and brought to a focus at F. Secondary Mirror Concave F Mirror Reflecting Telescope Eyepiece In contrast, the reflecting telescope uses a concave mirror for this purpose. Battery Safety Instructions CONTENTS • Always purchase the correct size (8 x 1.5V AA, 15A/15AC ANSI, LR6 IEC), (2 x ANSI/ Quick-Start Guide ........................................................... 4 NEDA-5004LC, IEC-CR2032) and grade of Refracting Telescope Features ...................................
    [Show full text]
  • The Great Refractor of Meudon Observatory Series: Astrophysics and Space Science Library
    springer.com Audouin Dollfus The Great Refractor of Meudon Observatory Series: Astrophysics and Space Science Library A definitive source of the Meudon telescope's history, written by a renowned astronomer The book is notable for the comprehensive documentation and attention to detail, tracing the genesis and construction of the telescope All works in the book have been theses and dissertations published by many prestigious, and sometimes lesser known, researchers The large telescope at Meudon has become legendary. When it was conceived, after 1870, astronomy as a whole was limited to visual observation. Knowledge of the sky was limited to what one could see, assisted only by optical means. The large telescopes produced at this time produced larger images, permitting close-up views: the Meudon telescope was able to 2013, XIII, 150 p. accomplish this perfectly. At Meudon, which became the Mecca of visual observation, the major planets were examined in a way that no other telescope had previously been able to. Printed book The telescope monitored the state of their atmospheres and mapped the appearance of their Hardcover surfaces. Through the telescope, one could obtain photographs showing the nuclei of comets, 119,99 € | £109.99 | $149.99 revealing their very small size, and by using an eyepiece one could measure the separation of [1] 128,39 € (D) | 131,99 € (A) | CHF double stars. With a marvellous little instrument, the polarimeter, the nature of clouds in 141,50 planetary atmospheres has been determined, and the type of surface material identified. Many Softcover more results were obtained, while photography, universally adopted, revolutionized other 102,79 € | £79.99 | $119.99 knowledge about the world.
    [Show full text]
  • BUILDING a SIMPLE REFRACTING TELESCOPE Grades 5–8
    BUILDING A SIMPLE REFRACTING TELESCOPE grades 5–8 Objective To build a simple refracting telescope. Introduction A simple refracting telescope is very easy to create. All that is needed are two convex lenses and two cardboard tubes. The first part of this activity demonstrates the inner workings of a telescope, and the second part demonstrates how to construct a simple refracting telescope. The lenses that will be used in this telescope are very similar to the lenses used by Galileo Galilei in the 17th century. Within a refracting telescope there are two lenses: an objective lens and an eyepiece. Part 1 of the activity demonstrates how light passes through the first lens and is bent (or refracted) to a focal point. Using a blank piece of paper, students can see where the focused image is formed. When another lens is placed on the opposite side of the piece of paper it acts like a magnifier, making the image appear larger. This arrangement of lenses demonstrates the simplicity of the basic telescope. Part 2 of the activity demonstrates how to construct a telescope and use it to view distant objects. The same lenses used in part 1 can be used in part 2 with the cardboard tubes to hold the lenses in place. The tubes slide inside each other to focus the telescope. After observing the process of light refraction without a telescope tube, students should have a clear understanding of what happens when they point their simple telescope at a distant planet or object. Background Reading for Educators Telescopes: Super Views of Space, available at https://www.amnh.org/learn-teach/curriculum-collections/discovering-the-universe/ telescopes-super-views-from-space Developed with the generous support of The Charles Hayden Foundation BUILDING A SIMPLE REFRACTING TELESCOPE Materials Set of lenses Styrofoam cups These can be ordered from Sergeant- 40–75 Watt red bulb Welch (1-800-727-4368) Desk lamp or flashlight part # WL53200-38L A and B, Scissors $0.99/lens) Blank piece of paper Transparent tape Note: These lenses can also be Set of cardboard tubes purchased in sets of 20.
    [Show full text]
  • Optical Telescopes
    Optical Telescopes Introduction The night sky always attracted people by its charming mystery. Observers had been using naked eyes for their explorations for many centuries. Obviously, they could not achieve a lot due to eyesight limitations. It cannot be estimated, how important the invention of telescopes was for astronomers. It opened an enormous field for visual observations, which had lead to many brilliant discoveries. That happened in 1608, when the German-born Dutch eyeglass maker had guessed to combine several lenses and created the first telescope [PRAS]. This occasion is now almost forgotten, because no inventions were made but a Dutchman. His device was not used for astronomical purposes, and it found its application in military use. The event, which remains in people memories, is the Galilean invention of his first telescope in 1609. The first Galilean optical tube was very simple, it could only magnify objects three times. After several modifications, the scientist achieved higher optical power. This helped him to observe the venusian phases, lunar craters and four jovian satellites. The main tasks of a telescope are the following: • Gathering as much light radiation as possible • Increasing an angular separation between objects • Creating a focused image of an object We have now achieved high technical level, which enables us to create colossal telescopes, reaching distant regions of the Universe and making great discoveries. Telescope components The main parts of which any telescope consists with are the following: • Primary lens (for refracting telescopes), which is the main component of a device. Bigger the lens, more light a telescope can gather and fainter objects can be viewed.
    [Show full text]
  • A6 4 Lunar View of La Bombonera
    Journal of Physics Special Topics An undergraduate physics journal A6 4 Lunar View of La Bombonera M. N. Chowdhury, D. Nutting, S. Mucesh and D. Watters Department of Physics and Astronomy, University of Leicester, Leicester, LE1 7RH November 7, 2016 Abstract We use principles from diffraction to estimate the required size for a reflecting telescope to watch an association football match at La Bombonera from the Moon. We determine that a mirror of diameter 1:13 (±0:08) km with focal length 17:00 (±1:15) km at focal ratio f/15 will be needed. Introduction It used to be suggested that a telescope could Observer be trained on the Moon to observe American on Moon dmin θf flags left by Apollo astronauts. However, this Football θf is far from possible due to the resolution of op- tical telescopes being limited by issues such as Rf diffraction and atmospheric seeing effects. We spin this idea and apply it to a sporting Figure 1: This demonstrates the trigonometry for esti- event. How large would a reflecting telescope mating the angular width of the football. Not to scale. have to be to watch a football match at La Bom- subtended by half the football, θf , using Equa- bonera, the home ground of Argentine club side tion 1: CA Boca Juniors? R tan θ = f (1) f d Theory min Newtonian telescopes use a primary parabolic where Rf = 11:15 (±0:16) cm is the football ra- mirror that focusses light from a distant source dius and dmin is the closest distance between the to a single focal point.
    [Show full text]
  • 400 Years of the Telescope
    TW O SMALL PIECES OF G LASS The Amazing Telescope Visual List/Script Blue = Computer Graphics Black = HD footage/video Red = Time Lapse photography Purple = Planetarium Graphics Scene I Visual I Audio Intro and title sequence 1. Circle showing a view through a simple Dramatic Music...starts slow and refractor as if the audience were looking through it. As it pans around it shows a view of builds the Moon, Jupiter with its moons, and the Milky Way. Fly through the telescope seeing two pieces of glass coming together in front of a fuzzy title, as they line up the title comes into focus. Fades to current star field. 2. Two spot lights representing bicycle lights move across a park entrance sign. A paper sign reads “Star Party Tonight” Lights fall off the sign. [The clatter of two bikes dropping to the ground is followed by the sound of feet walking on gravel.] 3. Youth 1 (The voice of the silhouette of a teenage girl appears facing audience) forward against a darken dome Hey, wait up! I can’t see. 4. Youth 2 The silhouette turns around to meet a second silhouette of a teenage boy OK. We’ll wait for your eyes to get use to the dark. 5. Youth 1 Why does it seem so dark here? 6. Youth 2 Scene I Visual I Audio Youth 1 stumbles, bumps into tree, startling an owl; Because we rode in from the bright lights of the city into the The yellow eyes of an owl appear. Glaring at the kids, he slowly blinks and flies off the tree.
    [Show full text]